System and method for scheduling travel on a charter transport

ABSTRACT

A method is disclosed for scheduling travel on a charter transport. The method can include obtaining from a traveler a passenger accommodation request identifying an origin-destination-pair. The method can also include automatically identifying one or more charter transports having an available passenger accommodation. Moreover, the method can include notifying the traveler of the available passenger accommodation.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No.12/366,439 filed 5 Feb. 2009, now U.S. Pat. No. 8200503 which is acontinuation of U.S. application Ser. No. 09/531956 filed 21 Mar. 2000,now abandoned the content of which are incorporated herein by referencein their entirety.

FIELD OF THE INVENTION

The present invention relates to the field of travel, and, moreparticularly, to a system and method for scheduling travel on a chartertransport.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be more readily understood through the followingdetailed description, with reference to the accompanying drawings, inwhich:

FIG. 1 is a block diagram of an embodiment of a system of the presentinvention; and

FIG. 2 is a block diagram of a device of the present invention.

DETAILED DESCRIPTION

There are approximately 800 charter jet operators in the United Statesoperating under the “Part 135” rules of the Federal AviationAdministration (FAA). Part 135 operators are “on demand” operators thatprovide non-scheduled charter service. Unlike scheduled operators, thetiming of the flight is at the discretion of the customer.

There are approximately 4,400 private jet aircraft in service today.Each year these planes fly an average of 260 flights. A small minorityof these planes are corporate jets. The vast majority of these planes,however, are owned by the 800 “Part 135” charter operators and arechartered by travelers on a per flight-hour basis. Charges vary betweena low of $1,200 an hour of flight time for a small Lear jet with acapacity of 5 to as much as $8,000 per hour or more for a largerChallenger with room for at least 10.

Typically, a traveler on a Part 135 plane charters the entire plane,rather than a seat on the plane. Thus, for example, when a travelercharters the plane for a trip from New York to Chicago for an overnighttrip, the plane stays at the airport and waits for that traveler.Charges for the overnight stay for the pilots are added. If the traveleris staying many days or only needs the jet one way, the plane willtypically immediately return to its home base and the cost of this“empty leg” or “deadhead” trip will be included in the rate for aone-way rental. It is estimated that there are over 114,000 empty legflights a year.

Today, the air charter industry has little incentive to fill empty legs,because each empty leg is already paid for by the person chartering theplane for the flight that creates an empty leg. For example, if someoneneeds to fly from Washington to Atlanta and return on the same day oreven the next day, typically the crew will wait on the ground for thepassenger(s) and an extra fee will be added for overnight accommodationsfor the crew. If that person only needs the plane one way, or if thepassenger(s) need to stay for an extended trip, the plane will return toits base that day. The charter operator then adds the cost of thisreturn trip to the cost of the charter. Some charter operators will thenattempt to fill this leg by calling charter operators in the city thatthe plane is returning from and ask them if they know of anyone needinga charter from that city to a city “in-line” and/or intermediate to thereturn destination. In most cases the trip will go unfilled. If it isfilled, the full rate for the plane is charged and, typically, a partialcredit is issued to the person who originally chartered the plane.

One embodiment of the present invention includes an Internet-basedreservation system, that allows charter jet operators to fill empty legsof charter flights by selling seats on these legs directly to travelers.A traveler can log onto the reservation system web site, see theavailability of seats on these jets, and purchase an available seat. Thesystem can handle the settlement charges and can take a fee for itsservices. Ultimately, by being able to fill the seats on a plane asopposed to simply chartering the plane, the system can dramaticallyreduce the cost of chartering and increase demand for private jettravel. Thus, the system has the potential to drastically increase theutilization of charter jets in the US and overseas.

FIG. 1 is a block diagram of an embodiment of a reservation system 1 ofthe present invention. System 1 can include one or more travelerinformation devices 110, one or more charter operator information device120, and a reservation server 130, each connected via a network 140.

Within system 1, traveler information device 110 can be used by atraveler to interact with a reservation service at server 130 to, forexample, request a passenger accommodation reservation, receive noticeof a passenger accommodation and/or reservation, provide payment for areservation, provide notice of delays, etc. Charter operator informationdevice 120 can be used by a charter transport operator and/or a chartertransport service operator to interact with a reservation service atserver 130 to, for example, communicate an availability of a chartertransport, submit bids to fulfill a passenger accommodation reservationrequest, receive notice of a passenger accommodation reservation,provide notice of charter run delays, receive notice of passengerdelays, receive payment for a passenger accommodation reservation, etc.

FIG. 1 also shows, using curved arrows, a method 2 of the presentinvention in the form of exemplary information flows within system 1.During exemplary information flow 10, a traveler can communicate arequest for a passenger accommodation reservation to the reservationservice. The request can include one or more origin-destination-pairs(e.g., city-pairs, airport-pairs, port-pairs, etc.), as well asdeparture dates and times and/or arrival dates and times. Any arrivaltime or destination time can be expressed as a specific time, such as9:00 AM. Moreover, any arrival time or destination time can be expressedas a time period, such as between 9:00 AM and 11:00 AM. Furthermore, anyarrival time or destination time can be expressed as a time limit, suchas, no earlier than 9:00 AM.

By way of further example, a traveler can send a request for two seatson a charter transport that is flying from Northern Virginia to HiltonHead, South Carolina on the morning of Jun. 12, 2000. Additionalrequests can be received from the same and/or different travelers.

During exemplary information flow 20, the reservation service canreceive information from the charter transport service operatorregarding the availability of a charter transport. By way of furtherexample, a charter transport service operator called RoyalAir can notifythe accommodation reservation service that a Lear having 3 availableseats will be departing Dulles Airport in Northern Virginia on Jun. 12,2000 at approximately 9:00 AM in route to Jacksonville, Fla.

After comparing the outstanding requests with the availabilityinformation, and detecting a match according to a match criteria, duringexemplary information flow 30 the reservation service can communicate anotification to the traveler of the availability of two seats (on theLear) corresponding to the traveler's request and offering to reservethose seats for the traveler and his/her companion.

During exemplary information flow 40, the traveler can accept the seatreservations and provide payment for the reservations. During exemplaryinformation flow 50, the reservation service can notify RoyalAir of thereservation and information regarding the passengers holding the seatreservations. During exemplary information flow 60, RoyalAir can notifythe reservation service regarding various issues related to the flightfrom Dulles to Jacksonville by way of Hilton Head, such as, for example,delays in departure, a possibility of departing earlier than thescheduled 9:00 AM time, changes in menu and/or drink choices, asubstitution of aircraft, etc. During exemplary information flow 70, thereservation service can relay these issues to the traveler, and/or canprovide a receipt for the earlier payment. During exemplary informationflow 80, the reservation service can provide payment to RoyalAir.

One of ordinary skill in the art can implement method 2 via system 1utilizing any of a wide variety of well-known architectures, hardware,protocols, and/or software. Thus, the following description of system 1can be viewed as illustrative, and should not be construed to limit theimplementation of method 2.

For example, traveler information device 110 and/or charter operatorinformation device 120 can be embodied as a land-line or wirelesstelephone, facsimile, personal computer, personal information manager,personal digital assistant, handheld computer, data terminal, and/orother similar device.

Each traveler information device 110, charter operator informationdevice 120, and server 130 can be considered a processing device. FIG. 2shows an exemplary processing device 210 that can, via its instructions,be adapted to provide the functions of traveler information device 110,charter operator information device 120, or server 130. Processingdevice 210 can include one or more processors 212, one or more memories214 containing instructions 216, one or more input/output (I/O) devices218, and one or more network interfaces 219.

In one embodiment, each processor 212 can be a general purposemicroprocessor, such a the Pentium series microprocessor manufactured bythe Intel Corporation of Santa Clara, Calif. In another embodiment,processor 212 can be an Application Specific Integrated Circuit (ASIC)which has been designed to implement in its hardware and/or firmware atleast a part of a method in accordance with an embodiment of the presentinvention.

Each memory 214 can be coupled, directly or indirectly, to processor 212and can store instructions 216 adapted to be executed by processor 212.Memory 214 can be any device capable of storing analog or digitalinformation, such as a hard disk, Random Access Memory (RAM), Read OnlyMemory (ROM), flash memory, a compact disk, a magnetic tape, a floppydisk, and any combination thereof.

Input/output (I/O) device 218 can be an audio and/or visual device,including, for example, a monitor, display, keyboard, keypad, touch-pad,pointing device, microphone, speaker, video camera, camera, scanner,printer, and/or port to which an I/O device can be attached orconnected.

Network 140 can electronically link physically distant travelerinformation devices 110, charter operator information devices 120, andservers 130 so that information can be transmitted and/or exchangedthere between. Network 140 can have any architecture, including a directconnection, a local area network, a wide area network such as the publicswitched telephone network and/or the Internet, and/or a combinationthereof. Network 140 can be a packet-switched, a circuit-switched, aconnectionless, or connection-oriented network or interconnectednetworks, or any combination thereof. Network 140 can be oriented towardvoice, data, or voice and data communications. Moreover, a transmissionmedia of network 140 can take any form, including wireline, satellite,wireless, or a combination thereof.

The software of system 1 can take any of numerous forms that arewell-known in the art. For example, server 130 can include and/or becoupled to one or more databases having a flat file or a relationalorganization, and a centralized or distributed architecture. Forinstance, those of skill in the art can tailor products such as an SQLdatabase to provide the functionality of method 2 and system 1.Moreover, tools such as HTML, XML, XSL, and WAP can be utilized forcommunications between device 110, device 120, and server 130.Additionally, system 1 can utilize platform-independent andnetwork-centric software such as Java or JavaScript, thereby potentiallyeliminating the need for server 130. System 1 can also include aGeographical Information System (GIS) within or coupled to server 130.Such systems are typically capable of understanding the spatialrelationship of various locations and of tracking the movement ofentities across such locations.

There are substantial advantages of the methods and systems of thepresent invention over the known methods and systems. For example,embodiments of the present invention can allow charter operators to holdtheir empty leg availability out to a much broader audience and increasetheir chances of filling these empty legs. Within the audience, thereare a large audience of executive travelers that would like theopportunity to fly in a private jet versus the standard commercialflight. Typically, these travelers are flying on full fare coach,refundable tickets and are making adjustments to their schedules at thelast minute. With system 1, travelers can check availability of seats oncharter flights through the Internet and book a seat on a flight.

Once they book the seat, travelers can be given all necessaryinformation required by the FAA, such as tail number, certificateinformation, etc. as well instructions on where and when to meet theirflight. They can also be given a number to call if they are runninglate. In one embodiment, once they arrive at the terminal, they willonly have to present identification. All tickets can be electronic. Aswith all charter flights, the plane crew can be responsible for assuringthe correct identification is presented and that people are briefed onthe safety issues for that aircraft. For each flight there can be anestimated departure time, typically a one-hour window. Unlike commercialflights, however, the plane has some flexibility as to when to leave andcan wait for passengers if they are running late, or can leave early ifall the passengers have arrived.

If demand for these seats outstrips supply, the reservation service canbecome a virtual airline booking charter flights through its existingcharter transport operator partners to fill this demand. If existingpartners cannot meet this demand, the reservation service can alsopurchase its own planes to fill seat demand between high volumeorigin-destination-pairs.

System 1 can operate as an 800 number service and/or a web site. Ifoperated as a web site, system 1 can have two major components, aninterface for charter transport operators and an interface fortravelers. The transport operator interface can provide screens to allowcharter operators to post empty leg availability of their jets and someturbo prop trips on planes such as a King Air. This interface can alsoallow them to maintain a calendar presentation of their overall flightschedules. This tool can make it easier for charter operators to posttheir schedule and track their overall inventory of flights.

The traveler interface can allow travelers to post passengeraccommodation reservation requests identifying the constraintsassociated with their travel, such as for example, theorigin-destination-pairs desired, the days and approximate times oftravel between each origin-destination-pair, the type of plane desired,meal and/or drink preferences, smoking preferences, etc.

Requests can be of several forms. For example, a request can be acommitted request, wherein if a flight is found that corresponds to thetraveler's request, a reservation is automatically made. In thissituation, the server can also automatically charge the passenger forthe booked reservation. A request can also be a notification request,wherein the server notifies the traveler of the availability of a flightmeeting some or all of the constraints identified in the traveler'srequest. This notification (and all notifications described herein) canoccur via any known method, including telephone, fax, pager, e-mail,and/or push technology to the traveler's browser.

Another form of request is a standing request, which would typically beplaced by a traveler who travels frequently between a particularorigin-destination-pair, such that any available seat corresponding tothat origin-destination-pair would generally be of moderate to highinterest to that traveler. For example, an entrepreneur who frequentlytravels between Memphis and Washington, D.C., and who has permanentlodging accommodations at both locations, may be able to adjust his orher business schedule to take advantage of many of the charter flightsthat arise between those locations having available seats. In thisexample, the server could automatically notify the traveler regardlessof the date and time period of the flight.

Requests can be received in any of several manners. A request can bereceived directly from a traveler. Also, a request can be received froman agent of the traveler, such as, for example, a travel partner of thetraveler, a family member of the traveler, a secretary of a traveler, atravel planner of the traveler, etc. Moreover, a request can be receivedfrom a commercial reservation system, such as, for example, the SABREsystem.

Similarly, travelers can be notified of available seats in any ofseveral manners. The traveler can be directly notified of the availableseat. Also, a notification can be sent to an agent of the traveler, suchas, for example, a travel partner of the traveler, a family member ofthe traveler, a secretary of a traveler, a travel planner of thetraveler, etc. Moreover, a notification can be sent to a commericalreservation system, such as, for example, the SABRE system.

System 1 can learn of available seats in several manners. In oneembodiment, each participating charter operator can initially provideserver 130 with a list of charter transports (e.g., airplanes,helicopters, limousines, yachts, sailboats, etc.) controlled and/ormanaged by that operator. For each transport, this list can includeinformation regarding the transport, including, for example, thetransport's identification number, its seating capacity, its travelcapabilities, maintenance records, license information, etc. Thereservation server can store this transport information in a database.In one embodiment, the reservation service can also store in thedatabase relevant information regarding the transport, such as, forexample any inspection ratings and/or scores for the transport, travelersatisfaction ratings for the transport, complaints regarding thetransport, etc.

Then, as empty legs become known to a charter operator, that charteroperator can communicate to the reservation server the identification ofthe charter transport and its availability (e.g., the dates and times itis available for use). Thus, once a reservation request is received, theserver can check its database for the available inventory of flights andseats and see whether there is a match or not.

Alternatively, a traveler can provide a passenger accommodationreservation request (e.g., a seat reservation request) to thereservation server, and the server can automatically seek bids tofulfill the seat request from a plurality of participating charteroperators. In one embodiment, the server can select the lowest bid andprovide it to the traveler. In another embodiment, the server canprovide any and/or all received bids to the traveler. The traveler canaccept any received bid and communicate this selection to the server,which can provide notification to the corresponding charter operator.

In either case, system 1 can automatically identify one or more chartertransports having an available passenger accommodation. A transport canbe automatically identified when it is identified without substantialhuman involvement. For example, in one embodiment, a transport can beidentified fully-automatically, wherein there is no human involvement.In another exemplary embodiment, a transport can be identifiedquasi-automatically, wherein the only human involvement is that neededto initiate a process by which a transport is identified. In yet anotherexemplary embodiment, a transport can be identified semi-automatically,wherein a list of transports is identified and communicated to a humanand the human selects the identification of the transport best meetingthe reservation request by, for example, selecting the transport andclicking an “Approved” button on a computer screen.

Travelers can reserve a seat by providing payment information, such ascredit card information. Moreover, either when placing a request or whenreserving a seat, a traveler can register with the accommodationreservation system. The registration information can include allnecessary information about the traveler such as, for example, name,addresses, phone numbers, emergency contacts, etc. Both the paymentinformation and the registration information can be stored by thesystem, thereby eliminating the need for the traveler to again provideit. Moreover, with this information stored, the traveler can accept andpay for a seat with a single action, such as, for example, by clickingon an “Accept Seat” button.

Once a traveler books a seat, they can be given all necessaryinformation, such as seat number, transport number, tail number, contactinformation, etc., as well instructions on where and when to meet theirflight. The passenger can also be given a number to call if they arerunning late. In one embodiment, once the passenger arrives at theterminal, they will only have to present identification. All tickets canbe electronic. As with all charter flights, the pilots can beresponsible for assuring the correct identification is presented andthat people are briefed on the safety issues for that aircraft. For eachflight there can be an estimated departure time, typically a one-hourwindow. As soon as all travelers arrive, the plane can depart. Unlikecommercial flights, the plane has some flexibility as to when to leaveand can wait for passengers if they are running late, or can leave earlyif all the passengers have arrived.

Travelers can be offered the opportunity to set up a premium servicewhere they input their frequent city pairs and request notification viaphone, fax, e-mail, push technology to the traveler's web page, or pagerwhen system 1 has an empty leg available for thatorigin-destination-pair.

The reservation service can establish a relationship with an on-linetravel provider to fill any unfilled travel requests. When requestsresult in a one-way that needs to be filled, intelligence can be builtinto system 1 to either offer to fill this through a traditionalcarrier, offer this sale to charter operators, or to fill this requestby matching it with others to fill a plane and create a new chartermanaged by the reservation service.

The reservation service can set up a frequent traveler program that canallow travelers to earn free trips as they accumulate points. Thereservation service can attempt to extend these benefits to existingfrequent traveler programs with each airline. The reservation servicecan also extend this service to American Express customers forMembership Mile members to accumulate points that can be used on otherairlines through American Express's existing program.

The architecture for system 1 can begin simply and evolve as demandgrows. Initially, system 1 can seek to only complete reservations forexact matches of origin and destination points of travelers that matchexactly those for the empty legs entered. This would mean that a flightfrom New York to Chicago would be matched by a filling an empty leg fromTeterboro to Midway, but not a flight from Teterboro to Los Angeles viaMidway. Little logic could be required and demand exactly matchessupply. This can narrow exact matches, though.

In a second phase, system 1 could allow for a lot more flexibility forboth travelers and charter operators. Here system 1 could match travelerrequirements with flight paths and routing to optimize the request forall travelers. There can be four main variables utilized in thismatching:

1. The geographic location of the plane at any given point;

2. The time that a flight occurs;

3. The price paid for a flight; and

4. The cost of a flight.

Each one of these variables can be subject to variation for a givenflight, although system 1 can restrict the fluctuation. For example,system 1 can establish a fixed price for all flights up to a certainmileage or certain operators may require that their planes leave fortheir home base within a predetermined time of their arrival at a givendestination. In addition, there can be economic limits that determinelimits for each variable. For example, for any given flight there can bea minimum charge for a passenger needed to recover the cost of carryingthat passenger.

Not all of these limits need be hard, and they can all be co-dependent.For example, a potential passenger may be willing to pay more for aflight from an airport that is 30 minutes from their house than for onethat is an hour's drive away. The same passenger, however, may bewilling to drive the extra distance in order to leave 30 minutesearlier. Thus, system 1 can allow a passenger to search for a flightfrom a given location at a given time and see in return results forinexact matches.

To determine how to make the matches, consider first the problem ofmatching only the start or end-point of any given flight. In this case,the variable ranges can be represented as an n-space, with matches ofindividual combinations represented as shapes within this n-space.

The ranges of each set of variables may not be symmetric and there maybe more than three sets of variables (for example number of travelersmay be yet another dimension). In any case each variable can becontinuous within each range and a function can be defined representingthe range of possible values for each variable. This function can have amaximum at the most desirable point within each range. The intersectionof the maxima for all variables can give the optimal combination for anyone set of possible combinations. This intersection can be thought of asa “center” for each set. It is possible that there may be multiplemaxima for a given set of combinations, but for the problem at hand suchcases can be decomposed into multiple instances each having a singlemaxima. For example, someone willing to fly for one price in the morningand a different price in the afternoon can be treated as two separatepurchasers. Thus, the process of matching seller and buyer can be a caseof finding the closest matches to the center for each set.

The entire problem set can be represented by a combination of theorigination and destination into a single entity known as a route. In amarket with a high number of buyers or sellers this might givesatisfactory results. Initially, however, this may not provide enoughmatches. In particular, system 1 may fail to find routes that couldotherwise be successfully broken into two or more pieces thus matchingmultiple requests. Thus, a given flight can be treated as a linked listrepresenting all possible routes within a given geographic area and agiven time span. Matching can then begin by matching flight originationtogether as a best match described above. If the destination fallswithin the range of possible destinations for the flight the possibilityis retained for further investigation. If a set of exact origination anddestination matches can be made then no further work is needed. If thedestination is not the flight's final destination then a new originationcan be created and can be used to possibly match other requestedflights. Similarly, matches can be made against destination and used togeneration possible origins.

The process of generating and matching new origins and destinations isthe classic “traveling salesman” problem, which is known to be NPcomplete. This means that as the number of possible endpoints grows asthe number of possible solutions grows non-linearly and the bestsolution cannot necessarily be found within a given finite time frame.

There are several approaches for finding close approximate solutions tothe traveling salesman problem. In particular, Monte Carlo and geneticalgorithms may be applicable as well as applying neural networks. In theworst case, generating anything approaching near time matches to Webrequests could require extensive hardware and still provide onlyaffirmative matches for exact matches. As a result, the process ofmatching flights and requests can be treated as an hour long processwith e-mails generated thereafter to the travelers telling them of theresults for a given request. Alternatively, the process of matchingflights and requests can be treated as an ongoing process which ends apredetermined time prior to departure.

Collection and presentation of the results can be through Web browsers,thus the de-facto standards of the Web can determine the architecture ofsystem 1. Moreover, system 1 can separate its presentation logic fromits business logic. Thus, a multi-tiered system with browsers,application servers, and database servers can be utilized.

Architecturally, in order to capture its main variables, system 1 canconsider four main entities:

1. Travelers;

2. Carriers;

3. Routes;

4. Accounts.

A traveler can become a passenger when a passenger accommodation (e.g.,a seat, cabin, bunk, etc.) reservation is booked in their name. Carrierscan operate one or more forms of transportation. That is, system 1 isnot necessarily limited to jets. Instead, system 1 can be utilized forreserving passenger accommodations on helicopters, yachts, sailboats,and even limousines. Routes can be determined by the capabilities of theforms of transportation in use. Accounts can track the costs andpayments.

Some of the basic relationships and sub-entities of these entities canbe as follows:

-   -   Travelers can book reservations for passenger accommodations;    -   Carriers can operate transports;    -   Transports can travel certain routes;    -   Routes can have costs associated with them;    -   Transports can have operating costs associated with them;    -   Travelers can book certain routes.    -   Routes can have an origination and a destination        (origin-destination-pair);    -   Routes can be traversed in a certain time period;    -   Travelers and passengers can have arrival and departure times.

Based on these conceptual requirements, a combination of exact and fuzzylogic can be used to match travelers to routes. Both forms of logic canbe handled by a fuzzy logic application since exact matches can be codedas discrete values (instead of ranges) within such an application.

As described above, embodiments of the present invention can provide amethod for scheduling travel on a charter transport. The method caninclude obtaining from a traveler a passenger accommodation requestidentifying an origin-destination-pair. The method can also includeautomatically identifying one or more charter transports having anavailable passenger accommodation. Moreover, the method can includenotifying the traveler of the available passenger accommodation.

Still other advantages of the present invention will become readilyapparent to those skilled in this art from the above-recited detaileddescription. Accordingly, the drawings and descriptions are to beregarded as illustrative in nature, and not as restrictive.

What is claimed:
 1. A computer implemented method for on-demand privateaircraft comprising: a. receiving by a computer based reservationservice from the owners or operators of private aircraft availabilityinformation including reservation criteria for an empty leg or sharedride flight, said reservation criteria including a departure location, adeparture time constraint, a minimum number of passengers, and an agreedupon payment schedule required to reserve the private aircraft; b.posting on a web site, by the computer-based reservation service, atleast a portion of the availability information relating to departurelocation and destination of various private aircraft; c. receiving viaits website by the computer based reservation service from prospectivepassengers preferred flight data for private aircraft, the preferredflight data defining at least one of empty leg flights and sharedflights selected by prospective passengers; d. said payment schedulebeing determined prior to said posting, and said payment scheduleincluding a cost per seat; e. receiving, by the computer-basedreservation service, reservation offers from a plurality of independentpassengers, each of the reservation offers including an agreement to aspecific destination request and a predetermined payment schedule; f.selecting a number of the received reservation requests, wherein theselected requestes collectively are consistent with said reservationcriteria for an identified private aircraft; g. communicating receivedreservation offers from one or more independent passengers to owners oroperators of private aircraft; h. receiving any changes in saidpredetermined reservation criteria and communicating said changes toeach of said independent passengers associated with the offers; i.accepting the selected reservation offers consistent with any saidchanges; j. communicating to each of the independent passengersassociated with the selected offers a passenger notification of theacceptance; k. communicating to an owner or operator of the identifiedprivate aircraft an owner or operator notification of the acceptance;and l. transmitting to the owner or operator of an identified privateaircraft a passenger list corresponding to the selected reservationoffers and a flight schedule that is substantially consistent with thedeparture time constraint, the departure location, and the specificdestination request.
 2. The method according to claim 1 wherein postingon a web site, by the computer-based reservation service, at least aportion of the availability information relating to departure locationand destination of various private aircraft includes the posting ofseveral private aircraft owned or operated by different entities atvarious locations throughout the United States.
 3. The method accordingto claim 1 wherein the aircraft listed includes aircraft of differentsizes.
 4. The method according to claim 1 wherein the departureinformation identified by a prospective passenger includes preferred dayof departure and number of passengers.
 5. The method according to claim1 wherein the cost per seat is adjusted depending on the number of seatssold.
 6. The method according to claim 1 wherein the passengers arenotified of a confirmed time and place of departure at least 24 hoursbefore departure time.
 7. The method according to claim 1 wherein eachpassenger independently agrees to the time, date, type of aircraft,place of departure and destination prior to agreement of owner oroperator to provide the agreed to service.
 8. The method according toclaim 1 wherein prospective passengers are apprised of a final flightschedule for an aircraft by a computer based system of communication. 9.The method according to claim 1 wherein the aircraft owner or operatoris apprised of reservation offers by a computer based system ofcommunication.
 10. The method according to claim 1 wherein payment byeach passenger is made to the reservation service independently.